Separating the effects of temperature and carbon allocation on the diel pattern of soil respiration in the different phenological stages in dry grasslands.

János Balogh,Krisztina Pintér,Zoltán Nagy,Marianna Papp,Szilvia Fóti,Débora Regina Roberti

doi:10.1371/journal.pone.0223247

János Balogh, Krisztina Pintér + Show 4 more

Open Access

https://doi.org/10.1371/journal.pone.0223247

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Journal: PloS one	Publication Date: Oct 17, 2019
Citations: 8	License type: CC BY 4.0

Affiliation: Magyar Agrár- és Élettudományi Egyetem

Abstract

Diel variability of soil respiration is influenced by several factors including temperature and carbon allocation as the most significant ones, co-varying on multiple time scales. In an attempt to disentangle their effects we analyzed the dynamics of soil respiration components using data from a three-year soil respiration study. We measured CO2 efflux in intact, root-excluded and root- and mycorrhizal fungi excluded plots and analyzed the diel variability in different phenological stages. We used sine wave models to describe the diel pattern of soil respiration and to disentangle the effects of temperature from belowground carbon allocation based on the differences between component dynamics inferred from the fitted models. Rhizospheric respiration peaked 8–12 hours after GPP peak, while mycorrhizal fungi respiration had a longer time lag of 13–20 hours. Results of δ13CO2 isotopic signals from the respiration components showed similar patterns. It was found that drought affected the component respiration rates differently. Also, the speed and the amount of carbon allocation to the roots as well as to the mycorrhizal fungi was reduced under drought. We conclude that the diel variability of soil respiration is the result of the integrated patterns of temperature- and carbon allocation-driven components in dry grasslands and their share depends on their phenological stages and stress state.

Highlights

The carbon balance of ecosystems is the sum of sink and source activities and exhibit large seasonal and interannual variability [1]
Despite the low sum of precipitation in 2011 the grassland acted as a sink of carbon and no drought period could be distinguished within this year (Fig 1)
We distinguished 4 phenological stages within each year of the study period according to the net ecosystem exchange (NEE), air temperature (T), soil water content (SWC) and normalized difference vegetation index (NDVI) variations (Fig 1)

Summary

Introduction

The carbon balance of ecosystems is the sum of sink and source activities and exhibit large seasonal and interannual variability [1]. Since the major part of the source activity is the result of soil respiration (Rs), the variability of this CO2 flux has a significant relevance in the carbon balance [2]. Soil respiration is a highly complex process including a wide range of soil biota (autotrophic and heterotrophic functioning) and different pathways of carbon cycling (decomposition, carbon allocation), all being under the control of environmental and biotic drivers [3,4,5]. Diel pattern of soil respiration among phenological stages were supported by OTKA-PD 100575 project. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript

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